FI103311B - ATM connection in a telecommunications network - Google Patents

Abstract

The invention relates to telecommunication networks and particularly to mobile networks using Asynchronous Transfer Mode (ATM) transmission systems. The invention also relates to the control of mobility and call control functions in ATM systems. According to the invention, a network element (MSC/BSC) of a telecommunication network, such as a mobile network, which in a conventional telecommunication network architecture ensures the switching of circuit-switched connections, is provided with an ATM switching function. ATM switching functions are controlled with the same call and switching control operations (31) that are conventionally used e.g. for the control of a TDM switching field (32) in a PLMN network element. In a minimum implementation, an ATM switching field (301) provided with a suitable control interface (30) is simply arranged in place of or parallel with the TDM switching field. The switching network element thus becomes an ATM network node of a physical or a logical interface layer. PLMN level signalling, mobility management and call control are implemented using solutions offered by existing mobile networks and current PLMN network elements.

Description

103311 ATM Switching in Telecommunication Networks Field of the Invention

The invention relates to telecommunications networks, and in particular to mobile communication networks using ATM (Asynchronous Transfer Mode) transmission systems. The invention also relates to controlling mobility and call control functions in ATM systems.

BACKGROUND OF THE INVENTION Two current trends in telecommunications are mobile and broadband networks. The term Broadband typically refers to a bit rate greater than 2 Mbit / s. Narrowband usually means a bit rate of 64 kbit / s or less. For bit rates between 64 kbit / s and 2 Mbit / s, the term "wideband" is sometimes used. There are at least two (compatible) reasons for the attractiveness of broadband networks: 1) Sharing a single broadband network service (bearer) between multiple users, some or all of whom do not need the full bandwidth alone, can provide benefits in terms of transmission system construction and flexibility.

2) Information transmitted over individual transmission channels may require their broadband. Users need new high-quality services, which in turn require high bit rates. Such services include, for example, video conferencing, high speed data transfer, etc. The common denominator of these services is multimedia, which combines image, audio and data .. into a single service.

• *

Because of its many strengths, ATM (Asynchronous Transfer Mode) is selected as a transmission technology in many standardized protocol structures of Broadband Integrated Services Digital Network (B-ISDN). In this context, «transfer« refers to the use of ATM switching and multiplexing techniques in the:: T: data link layer (i.e., OSI Layer 2, hereinafter referred to as ATM-v layer) for transporting end-user traffic from source to destination. • · • within the network. Virtual connections are established between the source and the destination, which requires switching functions on the network. Signaling and user information is normally carried over different virtual connections in the ATM layer 11 '> 2 103311. The virtual connection is identified in the ATM layer by the VPI of the Virtual Path Identifier and the VCI of the Virtual Channel Identifier.

In ATM, the information is transported chopped into fixed length cells, whereby the number of cells per time unit is proportional to the bandwidth requirements of the user. Each 53-octet cell is divided into a 5-octet header and a 48-octet information field, as shown in Figure 2.

The main purpose of the header is to identify the connection number for the cell sequence that constitutes the virtual channel for a particular call. Multiple virtual paths multiplexed in the ATM layer may be coupled to the same physical layer (i.e., OSI Layer 1), each path being identified by an 8-bit VPI in a User-to-Network Interface (UNI) and a 12-bit VPIL on the network node interface. Within each path, there may be a plurality of virtual channels, each identified by a 16-bit VCLI. The header-15 ko also includes other fields, such as Header Error Control (HEC), Generic Flow Control (GFC), Cell Loss Priorty (CLP), and Payload Type (PT).

The user-network interface (UNI) between the ATM terminal and the ATM switch 20 (private UNI) and the private and public ATM networks (universal UNI) and the associated UNI signaling Oa ATM cell) is defined at least j:; in the following different recommendations: [1] ATM User-Network Interface Specification, Version 3.1, ATM s Forum, 1994 ((iI 25 [2] ATM User-Network Interface (UNI) Signaling Specification, i .1 Version 4.0, ATM Forum , June 1994 • · [3] ITU-T Recommendation Q.2931 (1994) Broadband Integrated * · * 'Services Digital Network (B-ISDN), Digital Signaling System No. 2 (DSS 2),

User-Network Interface (UNI) Layer 3 Specification for Basic Call / Connection; 30 Control. ITU-T.

: T: In mobile networks, radio interfaces have traditionally been narrowband. Mobile network transmission systems have traditionally been implemented by circuit-switched connections with a star or tree network configuration. It has also been proposed to increase the capacity and flexibility of transmission systems: · '·' *: use of 35 different broadband packet switched transmission systems.

TH

1033113 in mobile communication networks, e.g. WO 9319559, WO 9400959 and EP 0366342. EP 0426269 discloses a mobile communication system in which base stations are connected by routers to Switches in an ATM network. Virtual connections are established between the base stations through the ATM network, controlled by the base stations. The rudimentary mobility control price is based on routing tables maintained at base stations and ATM switches, which are updated as subscribers move. GB2268359 and EP 679042 disclose an ATM access network having persistent ATM virtual connections between base stations and a mobile network interface which are allocated on a per call basis to speed up call switching.

ίο One possible future trend is mobile systems with a broadband radio interface. In this case, the transmission system of the mobile communication system must also be broadband, one of the potential alternatives being ATM technology.

The third trend is to bring wireless data communication (wireless ATM) 15 and mobility into ATM networks (wireless ATM). However, the problem is that the current B-ISDN and ATM standards do not in any way support the mobility management required by the mobile, the authentication of the subscribers, the call control, etc. Therefore, the introduction of these additional features required by the mobile seems to require considerable development and standardization work and major changes to existing ATM systems. This would mean that the implementation of the wireless ATM; would be a slow and expensive process.

• ·

BRIEF SUMMARY OF THE INVENTION One object of the invention is to provide an ATM transmission or ATM access network in a more flexible manner than before in mobile network architectures using traditional circuit-switched transmission systems.

It is yet another object of the invention to provide wireless data transmission ·· «v '· 30 and mobility to an ATM network without significant changes to existing ·: T: ATM networks and standards.

· * ·. One form of the invention is a communications network, such as a mobile communication network comprising mobile stations, base stations, at least one switching network element for call control and switching, and a switching function for connecting ATM virtual ATMs d. # 4 103311 masquerading between the base stations and said at least one controlling network element. The invention is characterized in that said ATM switching function is located in said at least one switching network element and is controlled by the call element control of the network element via an internal interface.

Another aspect of the invention is a wireless ATM network comprising mobile stations and at least one ATM switch to which base stations are connected via a user-network interface (UNI). The invention is characterized in that the ATM network has at least one network element controlling another telecommunication network, such as a mobile network, taking care of the call control and the switch control, said switching network element having an ATM switch function controlled by a network element between the base stations and the at least one controlling network element.

Yet another aspect of the invention is a network element interconnecting a mobile communication network. The invention is characterized in that the network element comprises an ATM switching function for dynamically switching virtual ATM transmission links to base stations, and that the ATM switching function is controlled by a network element call control via an internal interface.

Yet another aspect of the invention is the method of claim 1.

In the invention, a network element of a telecommunication network, such as a mobile network, which in the conventional telecommunication network architecture iiii; 2 5 takes care of circuit-switched connections, equipped with ATM switches /. 'Nine. The ATM switching functions are controlled by the same call and switching control functions as are traditionally used, for example, to control the TDM switch field in the PLMN network element. At a minimum, only the TDM switch is placed in place of, or in parallel with, the ATM switch field, which is provided with a suitable • · n: 3 0 control interface. In this way, the controlling network element is rendered as a single node of the ATM network in terms of physical and logical: **: '* · its communication layer. Example-: * ·. Therefore, in terms of PLMN signaling, mobility management and call control, the change is transparent so that they can be. , μ '': 'implemented using existing cellular network solutions as well as ii *; "· * 35 existing PLMN network elements with very minor modifications. This signifies * * - ^ ¾ 4 4« · # • ·

II

Tl 'Tl * Tl' t 103311 see reduced costs and even allow existing PLMNs to be equipped with an ATM transmission system. Furthermore, the invention enables the continuous evolution of telecommunications networks in the transmission system, since the use of ATM transmission can be extended to new network elements without the need for changes in higher-level system solutions.

The telecommunication network element of the invention may have both a conventional TDM switch field and a new ATM switching function in parallel. This is an advantageous solution, for example, in a network evolution control where the communication network includes both base stations using circuit switched transmission and ATM transmission or other network elements. The switching network element may then be arranged to connect the base station or other network element with either a virtual ATM connection or a circuit switched connection depending on whether or not that base station or other network element 15 supports ATM transmission.

In ATM layers, the telecommunication network element according to the invention operates in accordance with ATM standards and signals with other ATM devices (terminals or ATM switches), for example according to UNI signaling. Thus, the invention does not require any changes to the signaling and operation of the ATM network.

The PLMN network elements of the invention can also be used to bring mobility management and call control to a wireless ATM network. Thereby, one or more PLMNs according to the invention. the element is placed as part of the ATM network and the call control signaling is transmitted transparently through the ATM network. Because also virtual connections are connected. The 25 fields are executed on the PLMN network element, no other ATM network is required .. 'any mobility management features.

· ·: W1 'In a preferred embodiment of the invention, the PLMN element is connected to an ATM network via a UNI interface. Similarly, the base stations are connected to the ATM network via the UNI interface. The configuration of an ATM network can vary a lot »·« v: 30V. For example, it is possible that each base station is connected to the:: Ti UNI interface directly to a mobile switching center having an ATM switching function. In this case, the mobile switching center sees the base stations as ATM terminals to which virtual connections can be made. It is also possible that the base stations and the mobile switching center are connected via a UNI interface to a base station controller 4 'to 35 having an ATM switch function. The base station controller then sees the base stations and the mobile switching center as ATM terminals to which virtual connections can be made. The ATM switch function may be simultaneously in the mobile switching center and the base station controller.

In the invention, all the special network 5 test elements and special functions related to wireless communication can be implemented with the network elements and solutions already designed for cellular radio networks. This avoids designing special solutions for wireless ATM. These cellular network elements are connected to the ATM network via a standard UNI interface, but signaling between cellular network elements is performed either transparently through the ATM network through said permanent virtual connections or through separate signaling connections. In this way, the signaling associated with wireless communications does not cause any change to the standard ATM UNI protocol.

15 Brief Description of the Drawings

The invention will now be explained in more detail with reference to the accompanying drawings, in which Figure 1 illustrates a basic architecture for a telecommunications system in which. η the present invention can be applied, J 20 Figure 2 shows the structure of an ATM cell, Figure 3 shows a block diagram of a switching network element according to the invention; Figures 4-6 illustrate various GSM network architectures employing ATM technology, Figures 7, 8 and 9 are signaling diagrams illustrating the ATM connection connection according to the invention.

DESCRIPTION OF PREFERRED EMBODIMENTS _ j_: O: The present invention is applicable to all broadband ATM networks to bring wireless communication and mobility management to them. Correspondingly, the invention is applicable to any telecommunication network - - ·; r for implementing an inter-network transmission system using ATM technology.

In the following, the invention will be described using examples of mobile communication systems.

The mobile communication system used in its entirety or in which the network test elements are used to implement the wireless ATM.N can be any cellular radio system or other radio system. Different cellular systems may differ in number and function of different types of network elements. For example, cellular systems may have only mobile communication centers and base stations, or additionally base station controllers. Signaling can also differ significantly in different cellular systems. However, these differences are irrelevant to the invention, since one of the advantages of the invention is precisely the ability to maintain the signaling and network elements unchanged, except for the addition of an ATM switching function to one or more network elements. The control of the ATM connection according to the invention may take place through an internal control interface at the same call setup stage and by the same network element as specified in the system in question.

Also, the type of radio interface 15 between base stations and mobile stations is not relevant to the invention. The radio interface may be a narrowband, broadband, TDMA or CDMA, satellite, interface according to a current standard (e.g. GSM) or a radio interface according to a future standard (e.g. UMTS).

In the following description of preferred embodiments of the invention 20, the European Global System for Mobile Communication (GSM) is used as an example. The basic components of the GSM system are defined in the GSM recommendations. For the most important description of the GSM system, reference is made to these GSM Recommendations and the book "GSM System for Mobile Communications," by M. Mouly and M. Pautet, '25 Palaiseau, France, 1992, ISBN: 2-9507190-07-7.

Figure 1 illustrates a conventional GSM network consisting of mobile * MSs, base stations BTS, base station controllers BSC, and a mobile station MSC. special functions of the mobile network, such as voice: call control, mobility management, radio resource control, are implemented in the BTS, BSC and MSC of the PLMN network elements. The MSC takes care of call setup, call switching, and call control. The base station

The system consists of a base station controller BSC and base stations BTS. The base station controller BSC is used to control multiple base stations. The BSC may also control the handover between two BTSs connected to it. BSC has '35 defined A-interface towards MSC and Abis-interface to base station BTS

β 103311. These interfaces are defined in the GSM Recommendation. The base stations BTS provide a radio interface through which the mobile stations MS connect to the BSC and the MSC.

The mobile communication network PLMN also includes other network elements, such as the subscriber databases HLR (home location register) and VLR (visitor location register) and the operation and maintenance center OMC, not shown in Figure 1. The home location register HLR permanently contains subscriber data of subscribers and . The subscriber information of subscribers visiting the VLR-10 area is temporarily copied to the visitor location register VLR. At least one MSC provides a gateway to another network, such as PSTN. Such an MSC is called a Gateway MSC. Figure 1 further illustrates as a separate element the transcoder TC which performs various speech transcoding and rate matching operations. Functionally, the TC is between the BSC and the MSC, but is often physically located within the MSC. The transcoder TC is not essential to the invention, but is disclosed herein to illustrate various network configurations. Alternatively, the transcoder TC may be part of another network element, such as the MSC.

The GSM network elements can be classified according to the nature of the network elements into switching network elements and transmission network elements. The coupling network element has the ability (coupling field) to connect the units dynamically and selectively between transmission network elements. The transmission network elements transmit and receive user information, acting as transmission terminal devices. Typically MSC and MSC

1 25 BSCs are by their nature interconnected network elements, while MS, BTS and TC

^ * * are typically transmission terminal devices.

:: * In the conventional GSM network shown in Figure 1, transmission links • ·: '·· kit 11 between BTS-BSC, transmission links 12 between BSC-TC, transmission links: * ·': 13 between TC-MSC, and trunking transmission links 14 (e.g.

30 MSC-GMSC) are PCM circuit-switched links. The BSC, MSC, and GMSC comprise: * · * a time division multiplexed (TDM) switching field for selectively interconnecting PCM link circuits. As stated above, in order to increase the capacity and flexibility of the mobile network transmission systems, the use of ATM technology in mobile networks has also been made a condition. In the proposed solutions 35, the transmission links 11-14 of Figure 1 have been replaced by the ATM transmission I f · · ~ ϊ ~. I l »im and 9 103311 with a dedicated ATM switch (s) for switching virtual connections between different network elements.

According to the basic principle of the invention, the network element switching the PLMN network, such as the MSC or the BSC, is provided with an ATM switching field 5 which replaces or operates in parallel with the conventional TDM switching field. Figure 3 shows an MSC or BSC according to the invention. Figure 3 illustrates a call control 3 as a functional block of a conventional MSC / BSC, which generally represents all call control, mobility management, radio resource management, etc. resources that may be associated with call switching. The call control 3 has signaling connections 33 (e.g., SS7) to other network elements. Signaling connections can pass completely outside the ATM layer. Preferably, however, signaling connections 33 are persistent virtual ATM connections through which PLMN signaling is transparently transmitted in the payload of ATM cells. As will be illustrated below with reference to Examples 15, all PLMN signaling through signaling links 33 in the preferred embodiment of the invention is fully in accordance with GSM recommendations.

In Figure 3, the MSCIBTS is further provided with an ATM switching field (matrix) 301, which is controlled by the call control 3 via the interface unit 30. In the embodiment of Figure 3, the interface unit 30 comprises the following functional elements: a Management Information Base (MIB), an SIGN.CTRL control for ATM signaling, and an O&M switch -... interface 301 to this matrix. The ATM signaling control SIGN.CTRL takes care of the UNI signaling according to references [1] and [2], and controls the switching operations of the switching matrix 301 '25 via the O&M interface. Management Information Database- <I I '1' | The Management Information Base (MIB) maintains status and configuration information (management information) from the virtual routing and virtual channel connections available on the ATI switch UNI interfaces. The types of management information that may be available in the MIB include, for example: 30 physical layer: ATM layer; ATM layer statistics; Virtual Route Connections. * · *: (VPC); Virtual Channel Connections (VCC); and address registration information.

All interfaces between the ATM switching matrix 301 and other network elements (BTS, BSC, MSC, TC and / or ATM network switch) are i <'user network interfaces UNI. The UNI interface is defined in references [1], [2] 3 5, and [3], so that the ATM switching matrix sees the UNI interface attached to it.

• I <I

10 103311 PLMN network elements as conventional ATM devices (users) or ATM switches that it can reach over the UNI interface. The PLMN network elements without the ATM switching function are provided with an ATM adapter which forms a UNI interface towards the ATM network 3 and a PLNM interface towards the network test element 5.

In addition to the ATM switching matrix 301, the MSC / BSC according to the invention may also comprise a conventional TDM switching matrix 32, as illustrated by a dashed line in FIG. This solution may be used, for example, when other network elements are connected to the MSC / BSC both by circuit switched connections and ATM technology, and the MSC / BSC must be able to connect calls using both technologies. The MSC / BSC selects the switching technique used depending on whether or not the other network element supports ATM technology.

Figures 4-6 illustrate various evolutionary steps of GSM network architectures when applying ATM technology. In Figure 4, ATM technology is used for inter-exchange transmission (virtual trunking by ATM). In other words, the transmission links 14 of Figure 1 are replaced by ATM technology. In FIG. 5, circuit-switched transmission links 11 and 12 (FIG. 1) between base station controller BSC and base stations BTS and transcoder TC are replaced by virtual ATM connections. The BSC is equipped with an ATM switching function. In Figure 6, all transmission links 11-14 (Figure 1) are replaced by virtual ATM connections. Figure 6 is also the clearest picture in the present! the approach used in the invention. The base station controllers BSCs and switching MSCs (by nature of switching network elements) are equipped with an ATM switch 25 field feature so that they can switch virtual ATM connections. Between the BTS of the base stations and the TCs of the transcoders TC and other network elements which r: 'are of the transmission type. Figure 6 also shows a data element 61 as a network element, which generally means some kind of router, V *: gateway or similar to data network 62. The ATM transmission network 40, 50, or 60 in Figures 4-6 may be a normal ATM network including the actual ATM switches. The ATM network 60 may also be connected to other ATM networks 2, such as B-ISDN, or other data networks 4, such as N-ISDN, PSDN (e.g., X.25) or the Internet.

35 ATM networks 40, 50 and 60 can advantageously be a standard ATM network, ~ r ·

= - # «» I

733 f * ~ nm 103311 incorporating a wireless ATM concept with PLMN network elements with network architecture and ATM connectivity according to the invention. The likely ATM wireless network is of Figure 6 architecture.

Referring again to Figure 3, the call control 3 controls the switching matrix 5 by manipulating the management information related to the ATM layer and physical layer parameters in the interface unit 30. The interface unit 30 performs the virtual connection establishment, maintenance, and decommissioning according to UNI signaling.

Referring now to FIG. 7, an example of a call switch using a telecommunication network element having an ATM switching function according to the invention will be described. The example is applicable, inter alia, to the network architecture of Figure 5, where the BSC is a network element with ATM connectivity. By way of example, a handover (call transfer) between two BTSs connected to the same BSC which determines when to carry out the handover (as in the GSM system) will be described. The cellular network signaling shown is in accordance with GSM signaling. However, it is to be understood that the example is merely to illustrate one way in which a network element according to the invention can switch virtual ATM connections between two points. The invention is independent of which telecommunication system, network element or type of network signaling the invention is applied to.

As known in the MS, in addition to the serving base station, it measures downlink signals from a certain set of neighboring base stations. MS reports these mit-! background results are regularly provided to the base station controller BSC, which makes a handover decision based thereon. In Figure 7, the MS sends a measurement report to the current serving base station BTS_0 (hereinafter referred to as the "old base station") in a measurement report message. The BTS o transmits the measurement report to the BSC (measurement report / result) via a persistent virtual connection PVC2 in ATM cells.

Now suppose that the BSC, based on the measurement results transmitted by the MS (and according to the handover algorithm used), decides that the call should be transferred from the old base station BTS_o to the new base station BTS_n.

BSC makes the necessary radio resource reservations. and 35 tells the new base station BTS_n to activate the traffic / radio channel with a CHAN • m »103311 NEL_ACTIVATION message. In a preferred embodiment of the invention, each radio channel of the base station BTS has a predetermined address and port on the base station's ATM adapter and UNI interface. This allows the BTS_n to connect the allocated traffic / radio channel to the correct ATM connection. Assume 5 that the address of the now allocated traffic / radio channel is addr_1 with certain VPI / VCI values associated. BTS_n acknowledges by sending a message CHANNEL_ACTI-VATION_ACK.

The BSC sends a message HAND-OVER_COMMAND to the old base station BTS_o. This message contains information about the new base station 10 BTS_n. A handover from the old base station to the new base station is then performed according to the GSM recommendations. As a result of the handover, the radio interface traffic channel reserved for the call of the new base station BTS_ is connected to a logical connection established between the BSC and the new base station BTS_n. The GSM signaling associated with the handover is not essential to the invention and is not described further here. For a more detailed description of the messages in Figure 7, reference is made to the above book and to GSM recommendations.

When the BSC has received from the new base station BTS_n information (HANDOVER_COMPLETE) that the handover has been performed on the radio path, the BSC switches the call from the old base station BTS_0 to the new base station BTS_n and disconnects the old base station BTS_0. The associated ATM signaling is shown in the broken line of FIG. . . The signaling of the blocks 70 and 80 is also illustrated in FIGS. 8 and 9, respectively, which further shows an example of, 25 messages to be exchanged between elements inside the BSC of FIG. 3. . However, it should be noted that the internal operation and structure of the BSC are freely implemented and are not in any way limited to the examples in Figures 3, 8 and 9.

v: Referring to Figures 7 and 8, BSC call control 31 (Figure 3) provides. and command 30 to interface unit 30 to connect the traffic channel as a virtual circuit between the new base station BTS_ and the BSC. More specifically, the call control 31 transmits a connect command to the signaling control unit SIGN-CTRL. The connect command comprises as parameters the addresses of the new base station BTS ~ n and addr ~ 1 and the address of the other party (e.g. the TC) addr__2 address. 35 Addresses can be ATM or E.164 addresses. Thereafter, the signaling control-

f =, ... I

: '· · · · 11' T · '71: f 13 10331 1 SIGN-CTRL requests the ΜΙΡ database by using the getjnfo (ATM switching matrix 301) command with the ports to which addr_1 and addr_2 are connected. The MIP gives the port numbers in the info response as well as the VPI / VCI values that should be used for these connections. The signaling control SIGN-CTRL 5 then performs the normal ATM connection establishment procedure. In other words, the signaling unit SIGN-CTRL sends an ATM_UNI_Setup message to the new base station BTS__. The BTS_n accepts the call by sending an ATM_UNI_-Connect message. The virtual connection to the other party already exists, and need not be formed again in this example. Signaling a unit for lo-SIGN-CTRL commands through the O & M interface (a switch command) matrix for NCP-301 to connect the new base station BTS ~ n the VPI / VCI of the second party VPI / VCI ratio. Thereafter, the SIGN-CTRL gives the call control 31 an acknowledgment connect_ok.

Referring to Figures 7 and 9, the call control 31 of the BSC instructs the interface unit 15 to terminate the virtual connection between the old base station BTS_0 and the BSC. More specifically, the call control 31 sends a release command to the signaling control unit SIGN-CTRL. The Connect statement contains the traffic / radio address addr_3 allocated to the old base station BTS_o as parameters. Thereafter, the signaling control unit SIGN-CTRL ky-20 from the cause ΜΙΡ database with the command getjnfo (ATM switching matrix 301) to the port to which the addr_3 address is connected. MIP gives the port number in the info response and the VPI / VCI values used for this connection. Thereafter, the SIGN-CTRL signaling control performs the normal ATM disconnect procedure. In other words, the signaling unit SIGN-CTRL sends an ATM_UNI_Release message to the old 25 base station BTS_o. BTS_o acknowledges by sending an ATM_UNI_Release_Completed message. The SIGN-CTRL issues a release instruction 301 to the ATM '' ** 'switching matrix, which disconnects the old base station ··: * ·· BTS_o from the connection to the other party. After this, the SIGN-CTRL will give the call control 31 an acknowledgment con- nect_ok.

The BSC informs the MSC of the handover. The BSC of this remainder orders the old base station BTS_0 to release radio channel resources by transmitting a GSM message RF_CHANNEL_RELEASE. BTS_0 i · 'acknowledges by saying RF_CHANNEL_RELEASE_ACK. Now the handover has been completed 35.

14 103311

When the MSC / BSC needs to establish virtual connections to both parties before connecting (for example, during a call set-up), it sends the ATM_UNI_Setup message described above to both parties. Each party responds by saying ATM_UNI_Connect. The other party may be, except a PLMN network element, an ATM switch, or an ATM master.

The accompanying figures and the description related thereto are intended only to illustrate the present invention. The details of the invention may vary within the spirit and scope of the appended claims.

• • • • • • «« 1 • · · T 3¾ · ♦ · • · ♦ • I · - J ·· ♦ »« · • · · f («- ~ I» 1: 1 ·; __ «« 1 · 1 · f · ^ mm TTmm

Claims (15)

1. Telecommunication networks such as a mobile network comprising mobile stations (MS), the base station (BTS), at least one switching network element (BSC, MSC) providing the call control and switching, and a 2. Wireless ATM network comprising mobile stations (MS) and at least one ATM coupler to which the base station (BTS) with interface (UNI) is connected, characterized in that the ATM network is provided with at least one controlling network element (MSC, BSC) in another telecommunications network, such as a mobile network, to provide the call control and switching control, said switching network element (MSC, BSC) is provided with an ATM switching function (301) which is controlled by the network element's call control (31) via an internal interface, for dynamic coupling of virtual ATM connections between the base stations (BTS) and said at least one controlling network element. 3. A network according to claim 1 or 2, characterized in that there are permanent signaling connections for call control and mobility control signaling between the switching network element and each base station, and for the ATM switching function transparent signaling connections. A network according to claim 3, characterized in that said; signaling connections are permanent ATM virtual channels between the base stations and the switching network element. Network according to claim 1, 2, 3 or 4, characterized in that there is a subscriber network interface (UNI) between the base stations and the switching network element. ill : Network according to claim 1,2,3,4 or 5, characterized in that said telecommunication network further comprises the base station or | » other network elements coupled to said switching network element with time-division transmission links, and said coupling network element mm =,,,, | The circuit further comprises a time division switching field (32) for switching circuit switched connections. The ATM switching function for dynamic coupling of virtual ATM transmission links between the base stations and said at least one controlling network element, characterized by said ATM switching function (301) is arranged in said at least one switching network element (MSC, BSC). is controlled by ίο the network element's call control (31) via an internal interface (30). Network according to claim 6, characterized in that said switching network element is arranged to connect either a virtual ATM connection or a circuit switched connection to a base station or another network element depending on whether the base station or the other network element supports the ATM transmission. or not. 8. A network according to claim 1 or 2, characterized in that said at least one switching network element comprises a mobile telephone exchange (MSC) and / or a control unit (BSC) for a base station. Network according to any of the preceding claims, characterized in that the ATM switching function comprises means (30) which, in response to the control of the switching network element, perform an ATM switching function, a standard UNI signaling procedure between the base station and said second node. , with which a logical virtual channel for a call is formed, disconnected or reconnected. A method of mobility control and call control in a tree-free ATM network comprising mobile stations, the base station and at least one ATM coupler to which the base station is connected in the subscriber network interface (UNI), known as the functions relating to to the call control and mobility is performed in a separate switching network element in another telecommunications network, such as a mobile network, which network element is provided with an ATM switching function, the signaling relating to the mobility and the call control between the base stations and said network element in the mobile network is transmitted. • ·: ·. transparent via the ATM network in permanent logic virtual channels, • «· \ .. m call-specific logical virtual channels are formed between the base stations and the switching network element and / or other parties using the ATM switching function using UNI signaling, - v * ATM The switching function is controlled from the network element's call control unit, which connects via an internal interface. A method of mobility control and call control in a mobile network comprising mobile stations, the base station, at least one switching network element providing the call control and the mobility control, and an ATM switching function for dynamic switching of virtual ATM transmitters. connection connections between the base stations and the at least one switching network element, characterized by the functions relating to the call control and the mobility are performed in a separate switching network element in another telecommunication network, such as a mobile network, which network element is provided with said ATM switching function, the signaling to the mobility and call control between the base stations and the mentioned network element in the mobile network is transmitted lo transparently via the ATM network in permanent logical virtual channels, call-specific logical virtual channels are formed between the base stations and the switching network element. and / or other parties using the ATM switching function using UNI signaling, the ATM switching function is controlled from the network element's call control unit which switches via an internal interface. 12. A switching network element in the mobile network, characterized in that the network element comprises an ATM switching function for dynamic coupling of virtual ATM transmission connections to the base station and that the ATM switching function is controlled by the network element's call control via an internal interface. Network element according to claim 12, characterized in that it further comprises a time-divided switching field for switching f I · 3 circuit switched connections. Network element according to claim 13, characterized in that: it is arranged to connect either a virtual ATM connection or a ....: circuit-switched connection to a base station or another network element depending on - - -L: ·, the relevant base station or other network element supports or does not support the ATM transmission. A network element according to claim 12, characterized in that it comprises ... a mobile telephone exchange and / or a base station controller. ~ 7 ~~ · * · • I i • · · • »* • · · ra *